JP4941017B2 - OPTICAL AMPLIFIER, ITS CONTROL DEVICE, CONTROL CIRCUIT, CONTROL METHOD, CONTROL PROGRAM, AND OPTICAL COMMUNICATION NETWORK - Google Patents

Description

  The present invention relates to control of an optical amplifier.

  In recent years, with the spread of optical communication networks, new optical communication networks are being built in various places. In order to spread the optical communication network, a design that suppresses the cost is required.

  The technology of an optical amplifier that amplifies an optical signal transmitted through an optical fiber is an important element technology of an optical communication network. A rare earth-doped optical fiber amplifier is known as an optical amplifier. As a typical rare earth doped optical fiber, an optical amplifier (EDFA, EDF Amplifier) using an erbium doped optical fiber (EDF, Erbium-Doped Fiber) is exemplified. As another example of an optical amplifier, a Raman amplifier that amplifies an optical signal using stimulated Raman scattering of an optical fiber used as a normal transmission line is known.

Patent Document 1 describes an optical fiber amplifier and a control method thereof.
Patent Document 2 describes an optical amplifier.
Patent Document 3 describes an optical receiver for optical surges.
Patent Document 4 describes an optical amplifier.
Japanese Patent Laid-Open No. 2004-282025 JP 2006-120969 A JP 9-31618A JP 2002-084024 A

An object of the present invention is to provide an optical amplifier that is resistant to transient fluctuations.
Another object of the present invention is to provide an optical amplifier that can be easily controlled even when there are a plurality of laser diodes that supply pumping light to a rare earth-doped optical fiber.
Still another object of the present invention is to provide an optical amplifier having a simple configuration that does not require monitoring of an output signal level.
Still another object of the present invention is to provide an optical amplifier that can easily switch between different controls such as constant gain control, constant output control, constant gain and constant output control.
Still another object of the present invention is to provide an optical amplifier suitable for a multi-wavelength optical signal.
Still another object of the present invention is to provide an optical amplifier capable of amplifying a signal regardless of the signal modulation scheme and bit rate.

  In the following, means for solving the problem will be described using the numbers used in [Best Mode for Carrying Out the Invention] in parentheses. These numbers are added to clarify the correspondence between the description of [Claims] and [Best Mode for Carrying Out the Invention]. However, these numbers should not be used to interpret the technical scope of the invention described in [Claims].

  An optical amplifier according to the present invention includes an extraction unit (10) that extracts an optical signal from a first node on an input side optical fiber, and an excitation light supplied from the second node (11) from the input side optical fiber (IN). The rare-earth-doped optical fiber amplifier (40) that amplifies the input optical signal (90) and outputs the amplified optical signal to the output-side optical fiber (OUT), and the excitation light is controlled based on the optical signal extracted by the extraction unit (10). And a control unit (50). The pump light is not controlled to respond in real time to the optical signal of the output side optical fiber (OUT).

  Preferably, the optical amplifier according to the present invention includes a monitoring unit (13, 22) for monitoring the level of reflected light from the output side optical fiber (OUT), the optical signal extracted by the extracting unit (10), and the level of reflected light. And a characteristic monitor unit (70) for generating characteristic data indicating a change in the characteristic of the optical amplifier.

  Preferably, the optical amplifier according to the present invention includes a storage unit (51) that stores a correspondence relationship between a signal level corresponding to an optical signal of the input side optical fiber (IN) and a pumping level of pumping light. The control unit (50) refers to the storage unit (51) and controls the excitation light based on the excitation level corresponding to the optical signal extracted from the input side optical fiber (IN). The optical amplifier further includes a calibration unit (71) that updates the correspondence relationship of the storage unit (51) based on the characteristic data.

  In the optical amplifier according to the present invention, the calibration unit (71) performs updating according to the procedure stored in the storage unit (51) in advance so that the optical amplifier is automatically gain-controlled.

  The optical amplifier according to the present invention includes a variable optical attenuator (60) connected between a first node (10) and a second node (11) on an input side optical fiber. The control unit (50) controls the variable optical attenuator (60) based only on the input light extracted from the first node.

  The optical amplifier according to the present invention includes a variable optical attenuator (60) that is installed in the output side optical fiber and controls the output light of the rare earth doped optical fiber amplifier (40). The control unit (50) controls the variable optical attenuator (60) based only on the input light extracted from the first node.

The present invention provides an optical amplifier that is resistant to transient fluctuations.
Furthermore, the present invention provides an optical amplifier that can be easily controlled even if there are a plurality of laser diodes that supply pumping light to a rare earth-doped optical fiber.
Further, according to the present invention, an optical amplifier having a simple configuration that does not require monitoring of the output signal level is provided.
Furthermore, the present invention provides an optical amplifier that can easily switch between different controls such as constant gain control, constant output control, constant gain and constant output control.
Furthermore, the present invention provides an optical amplifier suitable for a multi-wavelength optical signal.
Furthermore, the present invention provides an optical amplifier capable of amplifying a signal regardless of the signal modulation method and bit rate.

  The best mode for carrying out the present invention will be described below with reference to the drawings. Solid lines in the figure indicate optical connections, and dotted lines indicate electrical connections.

  FIG. 1 shows a configuration of an optical amplifier according to a first embodiment of the present invention. The input side optical fiber IN is connected to the output side optical fiber OUT via the EDF 40. Connected to the output end of the input side optical fiber IN is an optical coupler 10 for dividing the input optical signal into the optical fiber F1 and the optical fiber F2. An optical signal input end of a PD (Photo Diode) 20 is connected to the output end of the optical fiber F2. A control circuit 50 is connected to the output terminal of the electric signal of the PD 20.

  The control circuit 50 includes a storage device 51 and a CPU (not shown). The storage device 51 stores a control program and control information. The control information indicates a correspondence relationship between the signal level corresponding to the input optical signal 90 and the target value of the excitation level of the excitation laser light of the LD 30. That is, the control information is information indicating a rule for uniquely deriving a control signal output to the LD 30 in accordance with an electric signal input from the PD 20, and can be realized by a table or function indicating a correspondence relationship. The control program is software executed by the CPU, and when an electric signal is input from the PD 20, a control signal to be output to the LD 30 is generated based on the control information.

  An output terminal of an LD (Laser Diode) electric signal is connected to the output terminal of the control circuit 50. The output end of the optical signal of the LD 30 is connected to the optical fiber F3. The optical coupler 11 combines the optical signals of the optical fibers F1 and F3 and outputs them to the optical fiber F4. The optical signal of the optical fiber F4 is supplied to the output side optical fiber OUT via the EDF 40.

  Such an optical amplifier operates as follows. An input optical signal 90 is input from the input side optical fiber IN. A part of the input optical signal 90 is branched for monitoring by the optical coupler 10 and is input to the PD 20 via the optical fiber F2, and the other part is input to the optical coupler 11 via the optical fiber F1.

  The PD 20 converts the input optical signal into an electric signal and transmits it to the control circuit 50. The control circuit 50 transmits a control signal to the LD 30 in response to the optical signal input from the PD 20. In response to the control signal, the LD 30 generates excitation laser light for exciting the EDF 40 and transmits the excitation laser light to the optical coupler 11 via the optical fiber F3. The input optical signal of the optical fiber F1 and the optical signal of the optical fiber F3 are combined by the optical coupler 11 and transmitted to the EDF 40. Er3 + (erbium ion) in the EDF 40 is excited by excitation laser light. The input optical signal input to the optical fibers F1 to F4 is amplified by Er3 + excited in the EDF 40 and supplied to the output side optical fiber OUT.

  As a modification of such an optical amplifier, as shown in FIG. 2, a configuration including a plurality of LDs is possible. In FIG. 2, the optical coupler 12 is inserted via the optical fiber 5 on the rear side of the EDF 40 as compared to FIG. 1. The optical coupler 12 is connected to an LD 31 that supplies pumping laser light to the EDF 40 from behind. The control circuit 50 includes control information and a control program that are the same as the LD 30 or independent of the LD 30 in order to control the LD 31. The control circuit 50 controls the excitation laser light of the LD 30 and the excitation laser light of the LD 31 based on the electrical signal generated by the PD 20.

The following effects are achieved by such an optical amplifier.
The first effect is that the output control of the optical amplifier can be performed only by monitoring the input signal level. Since control in response to the optical signal of the output side optical fiber OUT of the EDF 40 is not necessary, it is not performed.
The second effect is that only the input signal level is monitored, and the LD pumping light can be directly controlled in accordance with a preset optical output control method. It is more resistant to transient fluctuations.
The third effect is that the second effect can be controlled even when there are a plurality of LDs that can be controlled.
The fourth effect is that it is not necessary to monitor the output signal level as compared with the conventional optical amplifier that adjusts the LD pumping light by monitoring the input and output signal levels, so that the configuration is simplified.
The fifth effect is that the LD excitation level relative to the input level is controlled by various control methods (eg, constant gain control, constant output control, constant gain and constant output control) according to control information registered in advance in the storage unit. It can be done.
A sixth effect is that a control circuit that can freely switch the control method is realized by registering control information corresponding to the various control methods in the fifth effect in the storage unit and switching them according to an external command. Is Rukoto.
The seventh effect is that it can be applied as an optical amplifier for multi-wavelength optical signals.
The eighth effect is that the signal can be amplified regardless of the signal modulation method and the bit rate.

  In the present embodiment, the EDF has been described as an example. However, the above-described effect can be achieved with another rare earth-doped optical fiber, for example, a neodymium-doped optical fiber.

  FIG. 3 shows an optical amplifier according to the second embodiment. The optical amplifier in the present embodiment includes a VOA (Variable Optical Attenuator) 60. The optical amplifier 60 is interposed in the optical fiber F1 that connects the optical coupler 10 and the optical coupler 11 in the first embodiment. The control circuit 50 generates a VOA control signal based on an electrical signal input from the PD 20 by using a VOA control program and VOA control information stored in advance separately from the control program and control information for controlling the LD 30 and controls the VOA. To do. The VOA 60 is controlled based only on the optical signal extracted from the input optical signal.

  The VOA 60 is controlled by ALC (Automatic Level Control) by the VOA control program and the VOA control information. The LD 30 is controlled by AGC (Automatic Gain Control). By such control, the signal light input to the VOA 60 is adjusted so as to be constant output control, combined with the LD 30 by the optical coupler 11, and amplified and output by the EDF 40 so as to achieve constant gain control.

  FIG. 4 shows an optical amplifier according to the third embodiment. In the third embodiment, the position of the VOA 60 in the second embodiment is changed to the position on the output side of the EDF 40. An optical signal input from the input side optical fiber IN is branched by the optical coupler 10 and supplied to the optical coupler 11 and the PD 20. The control circuit monitors the level of the input signal branched to the PD 20 and refers to a previously stored table to perform ALC control on the VOA 60 and AGC control on the LD 30. The VOA 60 is controlled based on only the optical signal extracted from the input optical signal, as in the second embodiment. By this control, the signal input to the optical coupler 11 is combined with the LD 30 by the optical coupler 11, amplified by constant gain control by the EDF 40, and adjusted and output by the constant output control by the VOA 60.

  FIG. 5 shows an optical amplifier according to the fourth embodiment. Compared with the optical amplifier in the first embodiment, the optical amplifier in the present embodiment is connected to the optical coupler 13 that extracts a part of the reflected wave of the optical signal of the output side optical fiber OUT of the EDF 40. The extracted reflected wave can be used to compensate for a change in characteristics due to aging degradation of the LD 30 or the like.

  The device configuration of the optical path on the input side with respect to the EDF 40 of the optical amplifier in the present embodiment and the control of the optical device are the same as in the first embodiment. The optical coupler 13 is connected to the output side of the EDF 40. The optical coupler 13 combines the optical signal output from the EDF 40 and the signal output from the optical fiber F5, and outputs the combined signal to the output side optical fiber OUT.

  The PD 22 is connected to the terminal on the opposite side of the optical coupler 13 of the optical fiber F5. The PD 22 converts the optical signal extracted from the reflected light of the output side optical fiber OUT by the optical coupler 13 and transmitted through the optical fiber F5 into an electrical signal, and transmits the electrical signal to the characteristic monitor unit 70 of the control circuit 50.

  When the optical amplifier is operating normally, the pump laser light of the LD 30 is controlled so that automatic gain control is performed by the EDF 40. However, the gain in automatic gain control may be lower than the set value due to aging of the LD 30 (the problem that the output level decreases due to aging even if the LD control value is the same). In that case, the output level of the optical signal from the EDF 40 decreases.

  In such a case, the control circuit 50 calibrates a table for controlling the LD 30 based on the output light. Specifically, the characteristic monitor unit 70 of the control circuit 50 monitors the output optical signal by generating characteristic data indicating a change in the characteristic of the optical amplifier based on the electrical signal received from the PD 22. If the characteristic monitor unit 70 determines that the level of the output light is below a predetermined reference based on the characteristic data, the calibration unit 71 of the control circuit 50 uses a table prepared in advance according to a procedure defined in advance by a program. By rewriting (the control information described in the first embodiment), the control of the LD 30 is adjusted so that the output level of the EDF 40 is automatically controlled with the set gain.

  In the present embodiment, the optical signal on the output side of the EDF 40 is used only for calibrating changes in the characteristics of the optical amplifier over a relatively long period such as aging. The real-time control of the excitation laser light of the LD 30 does not need to use the output-side optical signal, and can be executed based only on the electric signal generated by the PD 20.

  FIG. 6 shows an optical amplifier according to the fifth embodiment. In the optical amplifier according to the present embodiment, a VOA 60 is interposed in an optical fiber connecting the EDF 40 and the optical coupler 13 as compared with the fourth embodiment. The characteristic monitor unit 70 of the control circuit 50 monitors the electrical signal output from the PD 22 and determines whether or not the deviation from the automatic gain control set by the EDF 40 exceeds a predetermined reference. If it is determined that the deviation exceeds a predetermined reference, the calibration unit 71 transmits a control signal to the VOA 60 and adjusts the output signal level of the VOA 60 to improve the accuracy of the output level.

  FIG. 7 shows an optical communication network to which an optical amplifier is applied. The optical communication network includes partial networks N1 to N3 connected to each other by long-distance optical cables L1 to L3. The optical amplifiers A1 to A3 having the configurations shown in the first to fifth embodiments are installed in the long-distance optical cables L1 to L3. Since the optical amplifiers A1 to A3 have a simple configuration, a highly reliable optical communication network can be constructed at low cost.

FIG. 1 shows a configuration of an optical amplifier according to the first embodiment. FIG. 2 shows a configuration of an optical amplifier according to a modification of the first embodiment. FIG. 3 shows a configuration of an optical amplifier according to a modification of the second embodiment. FIG. 4 shows a configuration of an optical amplifier according to a modification of the third embodiment. FIG. 5 shows a configuration of an optical amplifier according to a modification of the fourth embodiment. FIG. 6 shows a configuration of an optical amplifier according to a modification of the fifth embodiment. FIG. 7 shows an optical communication network.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 ... Optical coupler 11 ... Optical coupler 12 ... Optical coupler 13 ... Optical coupler 20 ... PD (photodiode)
30 ... LD (laser diode)
31 ... LD (laser diode)
40 ... EDF (erbium-doped optical fiber)
50 ... Control circuit 60 ... VOA (variable optical attenuator)
70: Characteristic monitor 71 ... Calibration unit

Claims (14)

An extraction unit for extracting an optical signal from the first node on the input side optical fiber;
A rare earth-doped optical fiber amplifier that amplifies an optical signal input from the input-side optical fiber by pump light supplied from the second node and outputs the amplified optical signal to the output-side optical fiber;
A control unit for controlling the excitation light based on the optical signal extracted by the extraction unit ;
A monitoring unit for monitoring the level of reflected light of the output side optical fiber;
A characteristic monitor unit that generates characteristic data indicating a change in the characteristic of the optical amplifier based on the optical signal extracted by the extraction unit and the level of the reflected light ; and
An optical amplifier in which the pump light is not controlled to respond in real time to the optical signal of the output side optical fiber. An optical amplifier according to claim 1 ,
And a storage unit for storing a correspondence relationship between a signal level corresponding to an optical signal of the input side optical fiber and a pumping level of the pumping light,
The control unit refers to the storage unit, controls the pumping light based on the pumping level corresponding to the optical signal extracted from the input side optical fiber,
Furthermore, the optical amplifier which comprises the calibration part which updates the said correspondence of the said memory | storage part based on the said characteristic data. An optical amplifier according to claim 2 ,
The calibration unit is an optical amplifier that performs the update according to a procedure stored in the storage unit in advance such that the optical amplifier is subjected to automatic gain control. An optical amplifier according to any one of claims 1 to 3 ,
And a variable optical attenuator connected between the first node and the second node on the input-side optical fiber,
The said control part is an optical amplifier which controls the said variable optical attenuator based only on the input light extracted from the said 1st node. An optical amplifier according to any one of claims 1 to 3 ,
And a variable optical attenuator installed on the output side optical fiber for controlling the output light of the rare earth-doped optical fiber amplifier,
The said control part is an optical amplifier which controls the said variable optical attenuator based only on the input light extracted from the said 1st node. An extraction unit for extracting an optical signal from the first node on the input side optical fiber;
Light extracted from the pumping light of the rare earth-doped optical fiber amplifier that amplifies the optical signal input from the input side optical fiber by the pumping light supplied from the second node and outputs the amplified optical signal to the output side optical fiber. A control unit for controlling based on the signal ;
A monitoring unit for monitoring the level of reflected light of the output side optical fiber;
A characteristic monitor unit that generates characteristic data indicating a change in characteristics of the optical amplifier based on the extracted optical signal and the level of the reflected light ; and
A control device for an optical amplifier in which the pump light is not controlled to respond in real time to the optical signal of the output side optical fiber. A storage unit for storing a correspondence relationship between a signal level corresponding to an optical signal of the input side optical fiber and a pumping level of the pumping light;
The pumping light of the rare-earth-doped optical fiber amplifier that amplifies the optical signal input from the input-side optical fiber by the pumping light supplied from the second node and outputs the amplified optical signal to the output-side optical fiber is transmitted on the input-side optical fiber. A control unit that performs control based only on the optical signal extracted from one node and the correspondence relationship ;
A monitoring unit for monitoring the level of reflected light of the output side optical fiber;
An optical amplifier control circuit comprising: a characteristic monitor unit that generates characteristic data indicating a change in characteristics of the optical amplifier based on the optical signal extracted from the first node and the level of the reflected light . An optical fiber network that is a communication medium for optical signals;
An optical amplifier for amplifying an optical signal transmitted by the optical fiber network,
The optical amplifier is
An extraction unit for extracting an optical signal from the first node on the input side optical fiber;
A rare earth-doped optical fiber amplifier that amplifies an optical signal input from the input-side optical fiber by pump light supplied from the second node and outputs the amplified optical signal to the output-side optical fiber;
A control unit for controlling the excitation light based on the optical signal extracted by the extraction unit ;
A monitoring unit for monitoring the level of reflected light of the output side optical fiber;
A characteristic monitor unit that generates characteristic data indicating a change in the characteristic of the optical amplifier based on the optical signal extracted by the extraction unit and the level of the reflected light ; and
The pumping light is not controlled to respond in real time to the optical signal of the output side optical fiber. Extracting an optical signal from a first node on the input side optical fiber;
Amplifying an optical signal input from the input side optical fiber by a rare earth-doped optical fiber supplied with pumping light from the second node and outputting the amplified optical signal to the output side optical fiber;
A control step of controlling the pumping light based on the optical signal extracted from the first node ;
Monitoring the level of reflected light of the output side optical fiber;
Generating characteristic data indicating a characteristic change in the rare earth-doped optical fiber based on the optical signal extracted from the first node and the level of the reflected light ; and
An optical amplifier control method in which the rare earth-doped optical fiber is not supplied with pumping light that responds in real time to the optical signal of the output-side optical fiber. An optical amplifier control method according to claim 9 , comprising:
A step of presetting a correspondence relationship between a signal level corresponding to a preset optical signal of the input side optical fiber and a pumping level of the pumping light;
In the control step, the excitation light is controlled based on the excitation level corresponding to the optical signal extracted from the input-side optical fiber in the correspondence relationship,
Furthermore, the control method of the optical amplifier which comprises the step which updates the said correspondence based on the said characteristic data. An optical amplifier control method according to claim 10 , comprising:
The update is performed according to a preset procedure so that the optical amplifier is subjected to automatic gain control. An optical amplifier control method according to any one of claims 9 to 11 ,
And a step of controlling a variable optical attenuator connected between the first node and the second node on the input side optical fiber based only on the input light extracted from the first node. Control method of optical amplifier. An optical amplifier control method according to any one of claims 9 to 11 ,
And a step of controlling a variable optical attenuator installed in the output side optical fiber and controlling the output light of the rare earth-doped optical fiber amplifier based only on the input light extracted from the first node. Control method. Extracting an optical signal from a first node on the input side optical fiber;
Amplifying an optical signal input from the input side optical fiber by a rare earth-doped optical fiber supplied with pumping light from the second node and outputting the amplified optical signal to the output side optical fiber ;
A control step of controlling the excitation light based on the optical signal extracted from the previous SL first node, and a control step of the excitation light is not feedback-controlled in response to real-time optical signal of the output optical fiber,
Monitoring the level of reflected light of the output side optical fiber;
An optical amplifier that causes a computer to execute characteristic data indicating a characteristic change in the rare earth-doped optical fiber based on the optical signal extracted from the first node and the level of the reflected light; Control program.

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